Dyed nitrogenous fibers and anionic dye composition therefor



United States Patent Ofifice 3 ,3 7 7,130 Patented Apr. 9, 1968 373,829! 3 Claims. (Cl. 8 54) ABSTRACT OF THE DISCLOSURE The applicants invention is a dyeing composition of .001.l6 part of an anionic metallized neutral-dyeing dye, an anionic milling dye or an anionic disperse dye, water, and alkylphenol-ethylene oxide condensate, a polyoxypropylene and polyoxyethylene condensate and an alkali metal salt of a sulfonated naphthalene. Nitrogenous fibers are dyed therewith.

This application is a division of our copending application Ser. No. 48,857, filed Aug. 11, 1960, now Patent No. 3,167,517, issued Jan. 26, 1965.

The present invention relates to a novel process for coloring nitrogenous materials at a pH of from about four to about six with available anionic dyes which previously could not be so utilized. Moreparticularly, it is concerned with a process for coloring natural and synthetic nitrogenous fibrous materials. l

Still more specifically, the invention also presents novel dyeing assistants which enable such nitrogencontaining materials to be colored with the desired dyestuffs and which at the desired pH range prevent such dyes from striking and exhausting too rapidlyLResultant dyeings are characterized by excellent strong, level, shades. They exhibit no physical damage to the material.

In general, the present invention may be used to color nitrogenous materials in various physical forms. These include, for example, sheets, films, rods, tubes, bristles and the, like. However, its most commonly encountered applications are in the dyeing of fibers, yarns and fabrics. Therefore, these fibrous structures will be taken as illustrative herein. For purposes of simplifying their identification, they w'ill be'r eferred to generally as nitrogenous fibers. However, it will be understood that this term is intended to include the various physical forms noted above. 7 A

As contemplated by the present invention, the term nitrogenous fibers includes both natural and synthetic materials, most of the latter being organic, hydrophobic materials. These fibers may be classified generally into two broad groups as (A) proteins and as (B) synthetics. As used in this discussion, Group (A) includes both natural and synthetic proteins, and Group (B) includes various types of synthetic, organic, nitrogen-containing, polymeric fibers derived from a polymerizable mixturecontaining at least of a basic nitrogen modifier.

The first and older group, Group (A) is often more precisely defined as a basic, nitrogen containing group, i.e., as materials wherein the nitrogen is present 'in a basic form. This class includes natural protein fibers such as wool, mohair, fur, hair, alpaca, real silk, Tussah silk and the like. It also includes synthetic protein fibers such as those derived from corn, peanuts, milk and the like. The natural fibers of Group (A) are referred to below as Type (1); the synthetics as Type (2).

In recent years, industry has developed a large number of varied synthetic fibers, each having desirable properties. Some of these comprise Group (B) of this invention. It includes various super-polyamides, known generally in the trade as nylons. These are referred to below as Type (3). Others include those often' called acrylic fibers, since many are polymers or copolymers of acrylonitrile. These include such typical illustrative copolymers as those of acrylonitrile and vinyl pyridine; acryl'onitrile, vinyl acetate and vinyl pyridine; combinations of these copoly mers; and acrylonitrile fibers wet spun from concentrated aqueous thiocyanate solutions. Materials of this general class are referred to below as Type (4). Another group is often referred to in the trade as modified acrylics. These will be referred to herein as Type (5). This type is illustrated, for example, by such copolymers such as those of acrylonitrile and vinyl pyrrolidone; acrylonitrile, vinylidine chloride and polyvinyl pyrrolidone; and the like.

Despite the varied, but advantageous, properties of these natural and synthetic fibers, in the past there has been available no satisfactory process by which they can be colored with some types of conventional .dyes at a pH in the range of from about four to about six. This problem has proved particularly troublesome with respect to the synthetics of Group (B) which in general are the most dffficult to dye. It is especially aggravated in the case of certain acrylic copolymers, i.e., those basic copolymers which comprise at least by weight of polymerized acrylonitrile and also contain at least one copolymerized basic comonomer.

TYPES OF DYESTUFFS UTILIZED One of the primary purposes of this invention is to provide a process by which nitrogenous fibers such as those of Types (1) to (5) can be satisfactorily colored at a pH of from about four to about six, making use of certain types of dyestutfs which previously could not be satisfactorily employed at this pH range. To this end, it is contemplated that this invention may utilize a wide 'selection among certain specific types of presently-available dyestuffs.

Those types of commercially-available dyes, suitable for use in coloring the fibers of Types (l)(5) in accordance with the present invention may be classified in various ways. In general, they fallinto three groups which are commercially characterized 'as (a) milling dyes, (b) prematallized dyes of the neutral-dyeing type, and (c) disperse dyes. All three fall within the general class of anionic dyes in which color is imparted by the negativelycharged portion of the molecule.

Milling dyes as a class generally comprise certain acid dyes which have excellent wet fastness properties when properly applied. For best results, they require careful application from a dye-bath having a pH of about six to eight. They will be referred to below as Type. '(A).

The neutral-dyeing prematallized dyes differ as a class from the older acid-dyeing type which dye levelly at a pH of about four to six. The latter contain sulfonic acid groups or alkali-metal salts thereof. In the neutral-dyeing. type with which this invention is concerned, the sulf onic groupings have been converted to some modified grouping such, for example, as the sulfonamides. This change in the molecular'structure also modifies the dyeing characteristics. Unlike the acid-dyeing type, they willnot dye levelly at the usual acid-dyeing'pH range of about Types (A) and (B). They dye from a dispersion of the 3 dye in an aqueous bath. However, like the dyes of Types (A) and (B), in the past it has only been possible to obtain the optimum results when the dye-bath has a pH of from about six to about eight. These dyes are referred to herein as Type (C).

COLORING REQUIREMENTS Coloring of fibrous materials encompasses, among others, at least two critical requisites. The first comprises removal of dye from an aqueous bath and depositing it upon the fiber. The amount deposited in the early stages of the dyeing is termed the strike. It is related to the attraction of the dye for the fiber. When two or more dyes are present, the dye first sorbed, or sorbed to the greater extent, by the fiber is that having the higher attraction, i.e., strike. Obviously, the greater the attraction between dye and fiber, the more rapid is the transfer of dye from the bath to the fiber.

The second requisite is the production of uniform sorption of dye by the fiber. Otherwise, a heathery, skittery, streaked or blotched appearance is imparted to the material. Ordinarily, however, obtaining uniform sorption connotes a lower attraction or lower strike.

Unfortunately, therefore, these two features present conflicting problems. It is always desirable to reduce the time period required in dyeing and still exhaust the dye bath. This is favored by greater attraction and more rapid sorption of the dye. But, conversely, production of a level dyeing of a good solid shade is favored when dyes are sorbed more slowly and have a lower attraction for the fiber so that they can dye off-and-on.

Dyes of the above-noted types (A), (B) and (C), contemplated in this invention, are well known to be substantive dyes, i.e., to exhibit tremendous fiber attraction, particularly for fibers containing basic-nitrogen groups of the types described above. Dyers have long known that to obtain good exhaustion of these dye-types from the dye bath, with minimized waste of an expensive dye, optimum conditions are obtained when the dye bath is at about the boil and also is acidic, of the order of pH 4-6.

Unfortunately, these conditions favor a strong strike, often resulting in unlevel dyeings which are not commercially acceptable. Accordingly, to prevent this he is forced to raise the pH of the bath to 6-8, and to lower the dyeing temperature. This results in much longer dyeing cycle with its concomitant increase in commercial expense and in waste of dye which also adds to the overall cost.

A third feature in obtaining good dyeing, although perhaps less critical, is the desirability of obtaining a maximum penetration of the dye into the fiber. Complete penetration is not always possible and may or may not occur during a particular dyeing cycle. When obtainable, it appreciably adds to the quality of a dyeing and results in maximum fastness of the dyed material. This third feature also conflicts with the first, since a dye having high afiinity for a fiber is likely to concentrate on the fiber surface and has less tendency or chance of migrating to the interior.

Although the primary purpose of a process in accordance with this invention is to obtain better dyeing of fibers of Types (1) to using dyes of Types (A), (B) and (C) at the optimum acidic and temperature conditions, it should be noted that to be considered successful, such a process also must meet certain additional criteria. For example, these would include: permitting (a) rapid strike while (b) obtaining uniform distribution of dye and (c) good exhaust; (d) level dyeing of material which had been unevenly scoured; (e) level dyeing of different fiber types used in the manufacture of blended yarns; (f) level dyeing of hard and soft yarns which have been used side by side in the weaving operation; (g) level dyeing of synthetic fibers which had been non-uniformly spun during manufacture, which causes uneven dyeing characteristics to be imparted to the fiber; and (h) level dyeing of piece material which had received uneven tensions during the weaving operation.

It is also important that the process shall avoid physical damage to the fibers. This is especially true too with respect to Group (B). It must not remove the vital crimp" which is imparted to such fibers during their manufacture to provide the elasticity or extensibility which is an absolute requirement in throwing and weaving operations and in the subsequent use of the fabric. Without this extensibility, the fiber, yarn or fabric is void of the life which the consumer demands. Consequently, an important step in the manufacture of most synthetic nitrogenous textile fibers is the crimping operation. It is not sufficient merely to put this crimp in. The dyeing process must not remove it.

In view of the commercial importance of the fibers of Types (1) through (5) and of the contemplated dyestulfs, there has been a long-standing need for a satisfactory dyeing procedure. Such a process for dyeing the presently contemplated fibers with the desired dyes at optimum conditions of acidity and temperature has not been available. A number of dyeing assistants to overcome the problem have been proposed. None have proved to be as satisfactory as the dyer needs.

Surprisingly, in view of the demand for such a process, and previous lack of success in providing it, according to this invention it has been found.

Even more surprising is the fact that despite the longfelt need for such a process, it now has been provided in the present invention and to a surprisingly successful degree. It provides a relatively simple dyeing process for nitrogenous fibers of both Groups (A) and (B). It produces a controlled strike; strong, level shades; surprisingly good penetration of the fiber by the dye; and the dye bath is satisfactorily exhausted. Excellent dyeings at the desired conditions are easily obtained in shorter dyeing times. Last, but not least, no observable damage to the fibers is produced.

In general terms, the improved dyeing process of this invention may be simply described. The fibers, in general, are dyed by the same operative steps employed in dyeing at the desired acidic and temperature conditions which were previously used with some acid dyes but could not be satisfactorily employed with the types of acid dyes with which the present invention is concerned. However, the procedure is modified by use in the dye bath of a novel type of dyeing-assistant composition.

In these broad terms, however, the modification seems more simple than is actually the case. The composition must be prepared in a quite specific manner. Moreover, the selection of components is critical, as is also, within certain limits, their relative proportions. The selection of components will be considered first.

The novel composition of this invention must contain at least two non-ionic surfactants, each of a specific type; and also at least one anionic surfactant of a specific type. All of the surfactants which are employed are of known types. In each case a number of such surface-active agents are readily available under a variety of commercial designations. It is their combination and the method of combining them which is responsible for the unexpected success of this invention.

One of the non-ionic types, must be of the alkyl aryl polyester alcohol type. These are commercially-available products obtained by condensing about one mol of an alkyl phenol with from about six to about ten mols of ethylene oxide. The alkyl moiety of the phenol should be a medium length chain of about six to ten carbon atoms. A typical illustrative product is that obtained by condensing one mol of nonyl phenol with nine mols of ethylene oxide. This first type of nonionic agent is referred to below as the Nl component for purposes of simplifying its identification.

The second type of nonionic surface-active agent should be a mixed polyoxypropylene-polyoxyethylene product, containing from about three to about five parts by weight of the polyoxyethylene to one part by weight of the polyoxypropylene. A typical illustrative product is the condensation product of about four parts by weight of polyoxyethylene with one part by weight of polyoxypropylene, the polyoxypropylene having a molecular Weight of about 00-1800 and the polyoxyethylenepolyoxypropylene condensation product having a molecular weight of about 8,000-9,000. For purposes of identification, this type is referred to herein as the N-2 or as the polyoxyalkylene component.

The anionic-type agent should be a sulfonated naphthalene, usually neutralized. The naphthalene moiety may, and usually will, have alkyl substituents. Usually the allgyl group will contain some four to eight carbon atoms. A typical illustrative example of an agent of this type is a mixed amyl-naphthalene sodium sulfonate in which the naphthalenes contain one, two or three amyl groups. For identification, this type is referred to below as the A-l or as the naphthalene component.

In the compositions of this invention, the weight ratio of the N-l to the N-2 type may vary from about 2:1 down to about 0.35:1. However, a ratio in the range of from about 1:1 down to about 0.421 is generally preferred. Its use will constitute a good practice. The combined weight of the non-ionic components present will indicate the amount of the A-l component to be used. The weight ratio of the combined weight of the non-ionic components to that of the anionic components may vary from as high as about 1.521 down to about 10:1.

When the dyeing assistant is added to-the dye bath it is necessarily diluted. Theoretically, then, there-is no upper limit on water content. Practically, however, this is unfeasible. The minimum total non-ionic content should be about eight weight percent and the maximum about sixty. Moreover, within the minimum 8% limit, neither of the required non-ionic agents should be present in amount less than about 2.7% nor more than about 40% within these limits, and observing the above-noted ratio limits, the range between minimum and maximum Weight percent limits for some of the components is shown in the following Table I.

TAB LE I Weight Percent Minimum v 0 amp orient Type Maximum TABLE II Component Weight Prcenf Item I Type i Max/ Typical In this Table I, no minimum can be given for water nor any maximum for A-l, or for Item (5 i.e.,

there are several reasons therefor.

It was noted above that the permissible maximum Item (3) is 60%. On the basis of the maximum weight ratio of non-ionics to Al, i.e., 1.5: 1, some 40% of A-l could be present, corresponding to a zero water content. This points up the fact that in Table I only the outside limits for any one Item are shown. The maximum contents and maximum ratios for all the Items can not be em- Just why a dyeing assistant composition of this type should cause the anionic dyes of Types (A), (B) or (C) to exhaust from the dye bath giving strong, level shades free from heathery or skittery effects, to'penetrate the fiber, thereby improving the fastness properties; to permit the color to dye oif-and-on, is not understood.

The amount of dyeingeassistant which should be used in the dye bath in a typical mill dyeing schedule will vary somewhat with the dye, the liquor ratio and the fibers involved. In general terms, using as illustrative the average composition of Table II, above, from about 0.25 to about four weight percent (OWF) Will be used in the dye bath. Ordinarily, from about 0.5 to about 1.5 percent constitutes a good practice and is generally preferred. Equivalent amounts of the composition having other concentrations may be used. Good results are obtained when the assistant is added to the dye bath. However, prewetting the fibers before dyeing with a dilute solution of the dyeing assistant is preferred.

As was noted above, a critical feature of the novel dyeing assistant of this invention is in the method by which it is prepared. Otherwise, a uniform, liquid composition is not obtained. A typical preparation of an illustrative composition is carried out as follows:

(1) Dissolve the N-2 component in all the water, usually at the ambient temperature.

(2) Add the A-1 and the N-1 components and heat the mixture with stirring to about l60-195 F., preferably to an average of about to F.

(3) Add mixture (2) to solution (1) slowly, with stirring,

then heat to the boil while continuing the stirring.

(4) Continue the stirring at the boil until the solution becomes uniform in appearance.

(5) Discontinue the heating.

(6) Continue stirring slowly as the mixture cools until it reaches about room temperature.

It is highly important that the cooling mixture be slowly stirred during the progress of Step (6). Otherwise, after cooling is completed, the composition will not be uniform. The completed, cooled composition is a clear amber liquid having a pH of about 7. It is slightly thixotropic, but is easily liquified by stirring.

Although various dyeing cycles may be used for various reasons, atypical dyeing procedure using the fluid dyeing assistant of the present invention may be outlined in the following steps:

(1) Add to the dyeing machine the normal amount of Water.

(2) Add about one percent (OWF) of the dyeing assistant in one to two gallons of cold water and add to the dyeing machine. i

(3) Enter the material to be dyed and wet it out for about ten minutes (or until thoroughly wet) with the dyeing assistant solution.

(4) Add the selected dye in amount of about 0.125 to about 4.0 percent (OWF) (depending on shade to be obtained) to water and add to the liquor in the dyeing machine.

(5) Dissolve about 3% ammonium acetate (OWF) in water and add to the dye liquor.

(6) While running the goods in the machine, turn on the heat and raise to the boil over some 30-60 minutes, usually about 45.

For dyes that are more difiicult to exhaust, after Step (7) some 0.5 to about 1.0 percent (OWF) of aqueous acetic acid (28%) or its equivalent may be added to the dye bath and the boiling continued for an additional period of some thirty minutes. This is then followed by Step (8) above.

As an alternative in Step the ammonium acetate may be replaced by the 0.5-1.0 percent of the 28% aqueous acetic acid or its equivalent. This procedure lowers the pH of the dye bath more than the addition of ammonium acetate. In turn, this usually reduces the length of time necessary to complete the dyeing. In the past, this usually was not a good practice. However, in the present invention, it may be done safely without danger of uneven strikes and commercially unacceptable dyeings.

It is a further advantage of the present invention that neutral-dyeing, anionic dyes may be applied by the above process to natural or synthetic material in the form of raw stock, yarns or fabrics.

The present invention will be further developed in conjunction with the following more specific discussion and the accompanying illustrative examples. Therein, unless otherwise noted, all parts and percentages are by weight and all temperatures are in degrees Fahrenheit. Concentration percentages in the bath are based on the weight of the fiber (OWF), unless otherwise noted.

In the following discussion and examples, certain specific fibers of Group (B) are tested as illustrative examples. For purposes of identification, they have been designated as Fibers A, B, C, D and E, respectively. These designations are used to identify fibers having the following compositions.

Fiber A is a commercially-available, polyamide fiber of Type (3) derived from hexamethylene diamine and adipic acid.

Fiber B is a commercially-available, self-condensation fiber of Type (3) derived from 6-aminohexanoic acid.

Fiber C is a commercially-available, acrylic copolymer of Type (4) derived from a mixture containing about 85% acrylonitrile and about 7.5% of each of vinyl acetate and monovinyl pyridine.

Fiber D is a commercially-available, acrylic copolymer of Type (4) derived from a mixture containing about 89% acrylonitrile and about 5.5% each of vinyl acetate and monovinyl pyridine.

Fiber E is a commercially-available modified-acrylic fiber of Type (5) derived from a mixture containing about 85% acrylonitrile and about vinyl pyrrolidone.

It is to be understood these five test fibers were selected merely for purposes of illustration of Types (3), (4) and (5) and that the process of the present invention is not necessarily limited to dyeing these specific fibers.

To illustrate the results obtained in attempting dyeing with dyes of Types (A) (B) and (C) but without the dyeing assistants of this invention at a pH ,below six in the acid-dyeing procedure outlined above, the following Examples l-4 are given. They are intended only for purposes of comparison.

' Example '1 A 250 ml. dye bath is prepared containing 250 ml. water, 50 mg. C.I. Acid Red 182 (1% OWF) and 150 mg. ammonium acetate (3% OWF). The dye is added to part of the water and then to the bath. The ammonium acetate is also dissolved in part of the water and added to the dye bath. A sample S-gram wool piece is then prewet with water, the excess water removed by passing the wet piece through a pair of squeeze rolls, and the wet piece is entered into the dye bath at room temperature. The ratio of the dye bath to wool is 50-1. The initial pH of the dye bath is about 6.1. The dye bath is slowly heated and the piece of wool is stirred. By the time the temperature has reached about F. substantially all the dye is exhausted. Heating and stirring are continued until the dye bath reaches the boil in about 45 minutes, and for about 45 more minutes at the boil. The dyed piece is then rinsed, washed and dried. The pH of the dye bath is then about 5.7. The piece is dyed unevenly, has a heathery appearance and the dyeing is commercially unacceptable.

Example 2 The procedure of Example 1 is repeated using a S-gram piece com-prising Fiber A, the piece containing structural defects. Again the dye from the bath is substantially exhausted by the time the bath temperature has reached 160 F. The dyed piece shows unevenly dyed portions (barr marks) and is commercially unacceptable.

Example 3 Six dye baths are prepared as in Example 1. Prewet sample S-gram pieces comprised of Fibers B, C, D, E, silk and mohair, respectively, are dyed, one piece in each dye bath, using the procedure of Example 1. In each dyeing, the dye bath again is substantially exhausted by the time the bath temperature reaches 160 F. The dyed pieces are unevenly colored and the dyeing is commercially unacceptable.

Example 4 Ten dye baths are prepared, each containing 250 ml. of water, 150 mg. of 28% aqueous acetic acid and 50 mg. respectively (1% OWF) of one of the following dyes:

Premetalizcd neutral-dyeing: (a) C.I. Acid Brown 19 (b) C.I. Acid Black 6 (c) C.I. Acid Blue A milling dye:

(d) C.I. Acid Black 26A (C.I. 27075) (e) C.I. Acid Green 16 (C.I. 44025) (f) C.I. Acid Orange 49 (C.I. 23260) (g) C.I. Acid Red 89 (C.I. 23910) (h) C.I. Acid Red 151 (C.I. 26900) (i) C.I. Acid Red 99 (C.I. 23285) A disperse dye:

(k) C.I. =Disperse Blue 3 In the preparation of each bath, the dye and the ammonium acetate are each first added to part of the water before addition to the bath. Each of the baths has a pH slightly below six. Ten sample S-gram pieces comprising Fiber A are then prewet with water, the excess water removed, and one wet piece entered into each of the ten dye baths at room temperature. Again dyeings are carried out a in Example 1, heating slowly (with stirring) to the boil in about 45 minutes and then dyeing at the boil for about 45 minutes. In each case the dyes exhaust very rapidly. The dyed pieces are then rinsed and dried. In

each of cases (a) to (i) the dyed pieces are unlevel and would be commercially unacceptable. In case (k) the desired dye value is not obtained. 3

Although unsatisfactory results were obtained in each of the preceding Examples 1-4, the unexpectedly improved results obtainable according to this invention are clearly shown in the following examples. In each is employed a dyeing assistant as required in the procedure of the present invention. For these examples, several dyeing assistant compositions were prepared. They are designated as Assistants A to E respectively. In each the N-l component is a condensation product of one mol of nonyl phenol and nine mols of ethylene oxide; the N2 component is a condensation product of 4 parts by weight of polyoxyethylene with one part of polyoxypropylene;

and the A-1 component is a mixed amyl naphthalene sodium sulfonate. v

Dyeing Assistant A is prepared as follows: About 25 parts of N-l and 6.25 parts of A-l are stirred together and-then slowly heated to about 180-F. About 25 parts of N-2 is added to about 44 parts of water, after which the hot mixture of N-l and'A-l is addedto the aqueous N-2 solution. The resulting'mixture is-thenheated to the boil with stirring and boiling and stirring is'continued until the mixture is uniform. The heat source is removed and slow stirring is continued until the-composition has cooled to about 25 C. The resultant cooledicom'position is a clear, amber-colored, viscous; slightly-thixotropic liquidhavingapHofabout7. :1 1. Additional dyeing assistant compositions are prepared using the same procedure and materialsrtAgain all parts are by'weight. i

Assistant B C N-l (parts). 18.75 13'. 75 1s. 75 2 5. A-l (parts). 1s. 75 13. 75 1s. 75 N-2 (parts). 12.50 13. 75 25.00 25. 00 Water (parts) 50.00 43. 75 37. 50 50.00

Example 5 Three 250-ml. dye baths are prepared, each containing 10 Example 9 The procedure of Example 8 is repeated substituting 100 mg. of 28% aqueous acetic acid instead of the 150 mg. of ammonium acetate. The initial pH of this dye bath is about 5.6, and the final pH about 5.7. The dye in the'bath exhausts onto the fiber more'rapidly than in Example 8. Even when the dyeing cycle is shortened by 30 minutes, the piece is well dyed a solid levelshade, is well penetrated'by the dye and the dyeing isof acceptable Example 10 Example 9 is repeated adding mg. ammonia to the dye bath, giving an initial pH ofabout 8.4 and a terminal 1 pH of about 5.6.The piece is dyed'a strong,'level shade 50 mg. of Acid Red '182 'and 150-mg. ammonium acetate. To the first bath i iadded 25 mg. Dyeing Assistant A (0.5% OWF); t0 the second. is added SOmgaof A (1% OWF); and to the third is added-100 mg. of A (2% OWF). Before addition to the bath, the assistant is diluted with about 5ml. of the dye-bath water. Sample S-gram wool pieces are prewet with Water, the excess water removed, and a Wet piece is entered into each-bath Dyeing is carried out.as in Example 1. The final pH-of the vdyebath is about 5.6 in each case. The dye exhausts much more slowly than in Example 1. The dyeings are stronger, more level, free of skittery or heathery effects, and. are. commercially acceptable. The improvement in le'velness of the shade of the dyed pieces increases as the amount of Assistant A is increased...ln thisexample, the greatest improvement occurs between the 0.5% and 1.0%, baths. On, increase to 2% a proportionately smaller increase in levelness is obtained. 1 Example 6 A dye bath is prepared'a's in Example 5, but adding thereto .abOutSO-mg. (1%.OWF.) of Assistant A.:A sam. ple S-gram piece of the same Fiber A material used in Exampley2 isdyed inthisbath, following the dyeing procedure of Example 2.FThe'dyed piece:has. a strong, solid .shade, is free from: barr marks and the dyeing is commercially acceptable. 2;:

Example 7 Five additional dye baths are prepared as in Example 6, each containing about 50 mg. (1% OWF) of one of Assistants A, B, C, D and E. A sample 5-gram wool piece is then dyed in each using the procedure of Example 1. In each case an improved result as compared with Example 1 is obtained. However, as compared with Assistants A to D, Assistant E produced a markedly smaller improvement, the resultant dyeing being barely acceptable. Assistants A to D inclusive, each caused good, solid, level shades commercially acceptable to be obtained.

Example 8 One percent of Assistant A is added to 250 ml. water, and a S-gram piece of woolen fabric is thoroughly wet with this solution. The excess is squeezed back into the bath and to the bath is added 50 mg. of Acid Red 182 and 150 mg. ammonium acetate. The prewet woolen piece is then returned to the bath and dyed by the procedure of Example 1. A strong level shade is obtained which is free from heathery or skittery etfects and is commercially acceptable.

which is well penetrated and the dyeing is of acceptable quality.

Example 11 Ten 250-ml. baths are prepared each containing 50 mg. Dyeing Assistant A, and .50 mg. acetic acid, 28% (1% OWF). To each *bath is'added one of the ten dyes, "respectively, of Example 4. Ten S-gram pieces of wool are prewet with water, the excess water removed, and one piece of wetted wool added to each dye and dyeing is done according to the dyeing cycle of Examples 1 and 4. The terminal pH of each bath is below six. Each of the pieces is dyed as'olid, level shade; free from 'skittery or heathery eiiects and the dyeing is of commercially-acceptable quality. r Example 12 Fixe dye baths are prepared, each containing 250 ml. water, 50 mgeDyeing Assistant A, 50 mg. Acid Red 182,

' and 50 mg. acetic acid, 28%. Five-gram pieces of mate- Assistant F G.

Example 13 Three 250-ml. dye baths are prepared each containing 50 mg. Acid Orange 54 and 150 mg. ammonium acetate. The first bath contains 'no dyeing assistant, the second bath contains mg. of Dyeing Assistant F and the third bath contains 100 mg. of Dyeing Assistant G. Five-gram wool pieces are dyed by the dyeing procedure of Example l. The piece dyed in the first bath is unevenly dyed and the dyeing is commercially unacceptable. The pieces dyed in the second and third baths have solid, level shades and the dyeings are commercially acceptable in quality.

In the foregoing discussion, a number of dyes of each of the three classes with which the invention is concerned have been discussed and/or tested. It is not intended the invention be limited thereto, other dyes of these classes being also useful in the practice of the present invention. In addition to those previously mentioned other illustrative dyes of the several types include but are not limited to the following.

In addition to those dyes discussed above, the following dyes may be used in the practice of this invention:

MILLING DYES Black 33 Blue 113 (CI. 26360) Blue 114 (CI. 26361) Green 9 (CI. 42100) Red 152 (C.I. 23010) Red 173 (CI. 23290) Violet 49 (CI. 42640) Violet 72 Green 19 (CI. 20440) (CI. 42665) Orange 45 Yellow 40 Orange 59 Yellow 44 Orange 83 (CI. 23900) Red 85 (CI. 22245) Yellow 63 Red 86 (CI. 24500) (C.I. 13095) Red 97 (CI. 22890) Yellow 82 Cl. Acid Yellow 117 Red 124 (0.1. 24820) Red 132 C1. Acid- NEUTRAL-DYEING PREMETALLIZED DYES C.I. Acid- C.I. Acid Black 8 Orange 64 Blue 166 Red 178 Blue 168 Red 219 Brown 29 Violet 68 Brown 47 Violet 78 Green 43 Yellow 113 Orange 60 Yellow 114 DISPERSE DYES C.I. Disperse-- C.I. Disperse-- Black 1 (Cl. 11365) Orange 3 Black 2 (CI. 11255) Black 3 (CI. 11025) Black 6 (Cl. 37235) Black 9 Blue 7 (CI. 62500) Blue 16 Blue 33 Green 1 (CI. 56060) We claim: 1. A dye bath composition containing, in parts per hundred parts of bath:

Orange 7 (CI. 11240) Red 1 c1. 11110 Red 13 (Cl. 11115) Red 15 (Cl. 60710) Red 31 (01. 11250 Yellow 3 (Cl. 11855) Yellow 5 0.1. 12790 (A) 0001-0160 part of an anionic dye selected from the group consisting of (a) the premetallized neutral-dyeing,

(b) milling and (a) at least 23% Water,

(b) from about 2.7 to about 40% of a first condensation product derived from an alkyl phenol and ethylene oxide,

(c) from about 2.7 to about 40% of a second condensation product derived from polyoxypropylene and polyoxyethylene,

(d) from about 0.8 to about 20% of at least one alkali-metal salt of a sulfonated naphthalene,

the weight ratio of the total weight of said first and second condensation products to the weight of said sulfonated naphthalene salt being from about 1.5 :1 to about 10:1 and the total weight of said first and second condensation products being not less than about eight nor more than about sixty weight percent of the dyeing-assistant composition; and

(C) about 0.0040.05 part of hydrogen-ion producing substance, said dye bath having an initial pH in the range 4-6.

2. A dye bath composition of claim 1 in addition containing sufiicient ammonia to produce an initial pH not greater than about 9.

3. A basic-nitrogen containing fibrous material dyed with a composition according to claim 1.

References Cited UNITED STATES PATENTS 1,372,038 3/1921 Phair 893 X 2,133,282 10/1938 Cook et a1. 893 X 2,305,691 12/1942 Grossmann 893 X 2,524,041 10/1950 Cook et a1 893 X 2,614,084 10/1952 Caeser et a1 893 X 2,630,411 3/1953 Harris 893 X 2,642,400 6/1953 Harris 8-93 X 2,674,619 4/1954 Lundsted 893 X 2,759,869 8/1956 Sutton et al 893 X 2,920,045 1/1960 Hearn et al 893 X 2,977,315 3/1961 Scheib et a]. 893 X OTHER REFERENCES Sisley: Nonionic Compounds, Their Employment in the Textile Industry, in American Dyestuff Reporter, vol. 38, No. 14, July 11, 1949, 8-83 (pp. 517-8). TP 890 A 512.

Diserens: Chemical Technology of Dyeing and Printing, vol. 11, Reinhold Pub. Corp., N.Y. (copyright 1951) (pp. 326327).

Antara Chemicals Catalogue, published by Antara Chem, New York, 1953, pp. 11-12 and 25-26.

Pluronics, published by Wyandotte Chemicals Corp., 1958, pp. 8-9.

DONALD LEVY, Primary Examiner. 

